TY - GEN
T1 - Physics-Informed Machine Learning Assisted Liquid Crystals µWave Phase Shifters Design and Synthesis
AU - Li, Jinfeng
N1 - Publisher Copyright:
© 2024, ICST Institute for Computer Sciences, Social Informatics and Telecommunications Engineering.
PY - 2024
Y1 - 2024
N2 - Liquid crystal (LC) has proven to be a promising material for microwave (µWave) phase shifters at GHz ranges, due to their continuous and wide tunability, as well as reasonably low absorption loss. However, designing LC phase shifters that meet specific application requirements (e.g., SpaceTech) is a challenging task that entails a complex trade-off between various parameters. Physics-informed machine learning (PI-ML) combines the power of machine learning with the underlying physics to develop a more accurate and interpretable model. Leveraging PI-ML to inform LC µWave device design is a relatively new area, with tremendous opportunities for exploration and innovation. In this article, a deep learning assisted LC µWave phase shifter design and synthesis framework is proposed. By incorporating physical constraints and knowledge into deep neural networks, one can effectively balance the trade-off between different design parameters and synthesize LC phase shifter structures that meet specific performance requirements (e.g., insertion loss, insertion loss balancing, phase tuning range, tuning speed, power consumption). The framework is envisaged to allow for the efficient and effective exploration of the design space, resulting in improved accuracy and efficiency compared to traditional two-stage design methods.
AB - Liquid crystal (LC) has proven to be a promising material for microwave (µWave) phase shifters at GHz ranges, due to their continuous and wide tunability, as well as reasonably low absorption loss. However, designing LC phase shifters that meet specific application requirements (e.g., SpaceTech) is a challenging task that entails a complex trade-off between various parameters. Physics-informed machine learning (PI-ML) combines the power of machine learning with the underlying physics to develop a more accurate and interpretable model. Leveraging PI-ML to inform LC µWave device design is a relatively new area, with tremendous opportunities for exploration and innovation. In this article, a deep learning assisted LC µWave phase shifter design and synthesis framework is proposed. By incorporating physical constraints and knowledge into deep neural networks, one can effectively balance the trade-off between different design parameters and synthesize LC phase shifter structures that meet specific performance requirements (e.g., insertion loss, insertion loss balancing, phase tuning range, tuning speed, power consumption). The framework is envisaged to allow for the efficient and effective exploration of the design space, resulting in improved accuracy and efficiency compared to traditional two-stage design methods.
KW - Liquid crystals
KW - Liquid crystals phase shifter
KW - Phase array
KW - Phase shifter
KW - Physics-informed machine learning
KW - Reconfigurable mmWave
KW - µWave
UR - http://www.scopus.com/inward/record.url?scp=85180810042&partnerID=8YFLogxK
U2 - 10.1007/978-3-031-50215-6_1
DO - 10.1007/978-3-031-50215-6_1
M3 - Conference contribution
AN - SCOPUS:85180810042
SN - 9783031502149
T3 - Lecture Notes of the Institute for Computer Sciences, Social-Informatics and Telecommunications Engineering, LNICST
SP - 3
EP - 13
BT - Emerging Technologies in Computing - 6th EAI International Conference, iCETiC 2023, Proceedings
A2 - Miraz, Mahdi H.
A2 - Southall, Garfield
A2 - Ali, Maaruf
A2 - Ware, Andrew
PB - Springer Science and Business Media Deutschland GmbH
T2 - 6th International Conference on Emerging Technologies in Computing, iCETiC 2023
Y2 - 17 August 2023 through 18 August 2023
ER -